JP3005865B2 - Ultrasonic motor drive circuit - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an ultrasonic motor driving circuit that generates a driving force by using a piezoelectric body.

[Summary of the Invention]

The present invention relates to a drive circuit for an ultrasonic motor, comprising a drive duty generation circuit that intermittently outputs a drive request signal based on a battery voltage, and a drive signal output unit that receives the drive request signal and outputs a drive signal. In addition, the driving signal is output in a burst form to improve the utilization rate of the battery capacity.

[Conventional technology]

Conventionally, the driving of the ultrasonic motor has been performed continuously. In order to drive the ultrasonic motor, a large current of several tens of mA was continuously supplied from the battery.

[Problems to be solved by the invention]

However, in the conventional driving method as described above, a large current of several tens of mA is continuously taken out of the battery to drive the ultrasonic motor, so that the battery capacity cannot be used effectively.

Generally, when a large current is taken out of a battery, only a smaller amount than the capacity of the battery can be used. This can be explained with reference to FIG. FIG. 2 shows the load characteristics of a certain battery. Curves A, B, and C represent load characteristics when the load resistance is set to small, medium, and large, respectively. For example, when the final voltage is 2.0 V, the current use capacity of each load resistor is about 5418 mAh on curve A and about 5486 m on curve B.
Ah, curve B is about 5645 mAh. From this, it is understood that the smaller the current taken out, the more effectively the battery capacity can be used.

Therefore, the driving method of continuously extracting a large current as described above has a disadvantage that the battery capacity cannot be used effectively.

[Means for solving the problem]

Therefore, in the present invention, in order to solve the above problem, the ultrasonic motor drive circuit detects a battery voltage based on an output from the control circuit and a control circuit for controlling the intermittent drive of the ultrasonic motor. A battery voltage detection circuit, a drive duty generation circuit that intermittently outputs a drive request signal based on an output from the control circuit and an output of the battery voltage detection circuit, and an intermittent drive of the ultrasonic motor based on the drive request signal And a driver for generating a drive signal for performing the operation.

In addition, the apparatus further includes a drive frequency generation circuit that generates a predetermined drive frequency signal for driving the ultrasonic motor based on an output from the control circuit, and the driver intermittently controls the ultrasonic motor based on the drive request signal and the drive frequency signal. It is desirable that a driving signal for driving be generated.

Alternatively, the apparatus further includes a phase shift circuit for adjusting the phase of the drive request signal and the drive frequency signal, and the driver intermittently drives the ultrasonic motor based on the output signal of the phase shifted circuit. A configuration for generating a drive signal may be adopted.

[Action]

According to the above configuration, the battery voltage is detected by the battery voltage detection circuit based on the control signal, and the drive duty generation circuit determines the idle period of the drive request signal and outputs the drive request signal intermittently based on the detected voltage. I do. Upon receiving the drive request signal, the drive signal output means outputs the drive signal intermittently. The driver supplies a current to the ultrasonic motor based on the output drive signal. Alternatively, when a phase shift circuit is used according to drive conditions, the drive signal is input to the phase shift circuit, and the driver supplies current to the ultrasonic motor based on the drive signal whose phase is shifted by 90 °. Therefore, the output from the driver becomes a burst having an idle period, and the idle period becomes variable as the battery voltage fluctuates. From the above, the battery capacity can be used effectively.

〔Example〕

 Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the present embodiment.
Reference numeral 1 denotes a control circuit which has an external ON / OFF signal and a frequency signal as inputs and controls driving of the ultrasonic motor. The drive duty generation circuit 2 outputs a drive request signal to the AND gate circuit 5 and the battery voltage detection circuit 3 according to the drive permission signal from the control circuit 1 and the battery voltage information from the battery voltage detection circuit 3. The battery voltage detection circuit 3 detects the battery voltage at the falling edge of the drive request signal output from the drive duty generation circuit 2 using the frequency signal from the control circuit 1, and outputs the result to the drive duty generation circuit 2. ing. One cycle of the drive request signal output from the drive duty generation circuit 2 is composed of “H” for a fixed time, and then “L” whose time changes according to the detection result of the battery voltage detection circuit 3.

This drive request signal is continuously generated while the drive permission signal of the control circuit 1 is being output. AND gate circuit 5
Indicates that the drive request signal of the drive duty generation circuit 2 is "H"
During this period, the driving frequency signal output from the driving frequency generation circuit 4 is output to the phase shift circuit 6. The phase shift circuit 6 outputs a frequency signal having a 90 ° phase shift when the drive frequency signal having the idle period of the AND gate circuit 5 is “H”. The driver 7 uses the frequency signal output from the phase shift circuit 6 to
A current is supplied to the ultrasonic motor to drive the ultrasonic motor intermittently.

The battery voltage detection circuit 3 detects the battery voltage at the falling edge of the drive request signal output from the drive duty generation circuit 2 using the frequency signal from the control circuit 1, and outputs the result to the drive duty generation circuit 2. . Then, the drive duty generation circuit 2 is based on the “H” level for a fixed time and the “L” level for a short time based on the battery voltage information, for example, when the battery capacity is sufficient, and long when the battery capacity is small. A drive request signal having an “L” level that changes with time according to the battery capacity, such as the “L” level of time, is output. Thereby, the battery capacity can be used effectively. In the present embodiment, the duty ratio of the drive request signal of the drive duty generation circuit is made variable by the battery voltage, but it is needless to say that the duty ratio can be made constant.

 Next, the present invention will be described with reference to more detailed examples.

FIG. 3 is a detailed circuit diagram of the control circuit 1 and the drive duty generation circuit 2 of the present embodiment. Here, the connection and operation of FIG. 3 will be described with reference to the time chart of FIG.

"The control circuit 1 has an input of an ON / OFF signal and a frequency signal from the outside, and controls the driving of the ultrasonic motor." The 128 Hz frequency signal from the outside is the first TFF11. In 1
Divided by 1/2 (64 Hz), and further divided by 1/2 (3
2 Hz) and input to the first D · FF13. The first D · FF1
3 has an external ON / OFF signal input, and when the ON / OFF signal is turned on, the signal a rises from “L” to “L”;
The Q output becomes “H” using the frequency signal of 32 Hz and is input to the differentiating circuits 14 and 15. The differentiating circuits 14 and 15 output a one-shot pulse signal e for one cycle of 128 Hz at the rise of the Q output of the first D · FF 13 using the signal of 128 Hz.

"The drive duty generation circuit 2 outputs a drive request signal in accordance with the drive permission signal from the control circuit 1 and the battery voltage information from the battery voltage detection circuit. One cycle is “H” for a certain period of time and thereafter consists of an “L” level that changes with the detection result of the battery voltage detection circuit 3, and continuously occurs while the drive permission signal of the control circuit 1 is being output. The 32 Hz frequency signal from the control circuit 1 is input to an output period setting 24-decimal counter 21 and a pause period setting hexadecimal presettable counter 23 of the drive duty generation circuit 2. When the output signal d from the first D · FF 13 of the control circuit 1 outputs “H”, the first RS latch 22 and the second RS latch 24 are reset. The output of the 24-hex counter 21 is connected to the input of the first RS latch 22 and the reset of the second RS latch 24, and the output of the hexadecimal presettable 23 is connected to the first RS latch 22. It is connected to the reset of the S latch 22 and to the input of the second RS latch 24, respectively.
Here, the output signal e from the differentiating circuits 14 and 15 of the control circuit 1
Is input to the second RS latch 24, and the second RS latch 24 outputs the "L" signal from the control circuit 1 at the reset terminal input, and at the same time the reset is released, The control circuit 1 outputs a signal “b” which becomes “H” at the rise of the one-shot pulse of the signal “e”. Thus, the output period starts, and the ultrasonic motor starts driving. This second R
The output signal b of the -S latch 24 is inverted through an inverter 45 to become a signal, and this signal is
The 24 decimal counter 21 starts counting at the falling edge of the signal. 24-decimal counter
21 outputs a one-shot pulse signal f after the end of counting. The output signal f of the 24-decimal counter 21 is the first RS
The signal is input to the latch 22 and the second RS latch 24. Thus, the output signal b of the second RS latch 24 falls from "H" to "L" at the rise of the output signal f of the 24-decimal counter 21, and at the same time, the 24-decimal counter is reset by the signal. As a result, the output period ends, the drive signal to the ultrasonic motor stops, and the pause period starts. Also, the first R-
The output signal 1 of the S latch 22 is the output signal f of the 24-decimal counter.
It goes to “H” at the rise of.

The D · FF 25 has the input signal b from the second RS latch 24 as an input, and uses the 64 Hz frequency signal inverted by the inverter 34 from the control circuit 1 to input the signal b.
, A signal g delayed by a half cycle of the 64 Hz frequency signal is output. The output signal g is input to the waveform shaping circuits 26 and 27, and outputs a one-shot pulse h at the falling edge of the signal g using the 128 Hz frequency signal from the control circuit 1. The one-shot pulse signals h from the waveform shaping circuits 26 and 27 are connected to the reset terminal of the hexadecimal presettable counter 23 through the gate circuit groups 29, 31 and 33, and the signal h is inverted through the inverter 28. Hex presettable counter through gate circuits 30 and 32
At the rising edge of the signal h, the hexadecimal presettable counter 23 is set according to the battery voltage information. An output signal 1 from the RS latch 22 is inverted through an inverter 46, and is inverted by a gate circuit group.
Through 29, 31, and 33, it is connected to the reset terminal of the hexadecimal presettable counter 23. The outputs S1 and S2 from the battery voltage detection circuit 3 are respectively connected to the gate circuit groups 31 and 32.
It is input to the hexadecimal presettable counter 23 through 29 and 30. For example, when the battery voltage is sufficient, the outputs S1 and S2 from the battery voltage detection circuit 3 are S1 = “L”, respectively.
A signal of S2 = “L” is output. When the battery voltage is 2.4V to 2.8V, S1 = “H”, S2 = “L”, and when the battery voltage is 2.4V or less, S1 = “H” , S2 = "H" are output. Here, taking the case where the battery voltage is 2.4 V or less as an example, the signals of the outputs S1 and S2 from the battery voltage detection circuit 3 each become “H”, the hexadecimal presettable counter 23 becomes 0000, and the control circuit After counting the frequency signal of 32 Hz from 1 for 16 cycles (0.5 seconds), the one-shot pulse K is output at the fall. At the rise of the one-shot pulse K, the first RS latch 22 is reset, and the second RS latch 24 rises from "L" to "H". When the output ends, the output period starts again, and the ultrasonic motor starts driving again.

By repeating the above operation, the ultrasonic motor can perform driving having a rest period according to the battery capacity.

Next, the connection and operation of the battery voltage detection circuit 3 in FIG. 4 will be described with reference to a detailed circuit diagram and a time chart in FIG.

“The battery voltage detection circuit 3 detects the battery voltage at the falling edge of the drive request signal b output from the drive duty generation circuit 2 using the frequency signal from the control circuit 1 and outputs the result to the drive duty generation circuit. The waveform shaping circuits 35 and 36 of the battery voltage detection circuit 3 have the input of the output signal b from the drive duty generation circuit 2 and use the 128 Hz frequency signal from the control circuit 1 to generate the signal b. On the downstream, a one-shot pulse i for battery voltage sampling is output. The outputs of the waveform shaping circuits 35 and 36 are
The first voltage divider 37 for dividing the battery voltage by resistance division and the second voltage divider 37
And a reference constant voltage 40, which is a constant voltage source that is stable against power supply fluctuations using the threshold voltage of the MOS transistor. First comparator 41
Compares the voltage of the reference constant voltage source 40 with the voltage of the first voltage dividing circuit 37 and detects, for example, -2.8 V of the battery voltage. Here, the output of the first comparator 41 is “L” when the battery voltage is sufficient, and is “H” when the battery voltage is 2.8 V or less. Similarly, the second comparator 42 compares the voltage of the reference constant voltage source 40 with the voltage of the voltage dividing circuit 38 and detects, for example, -2.4 V of the battery voltage.
Here, the output of the second comparator 42 becomes “L” when the battery voltage is sufficient, and becomes “H” when the battery voltage is 2.4 V or less. The NAND gate circuit 39 receives the signal from the control circuit 1
It has a 128 Hz frequency signal and an output signal i from the waveform shaping circuit at its inputs, the outputs of which are connected to the C inputs of D.FF43 and D.FF44. The outputs of the first comparator 41 and the second comparator 42 are D • FF43 and D • FF, respectively.
Connected to 44 D inputs. D • FF43 and D • FF44 are
Using the output of the NAND gate circuit 39, the first comparator
The output data of 41 and the second comparator 42 are latched. The output S1 of the D · FF43 and the output S2 of the D · FF44 each output a battery voltage detection result to the drive duty generation circuit.

〔The invention's effect〕

Since the present invention is configured as described above, it has a remarkable effect of improving the utilization rate of the battery capacity. Further, in the present invention, the pause time of the burst signal for driving the ultrasonic motor changes according to the battery voltage, so that the utilization rate of the battery capacity can be further increased as compared with fixing the fixed time.

This is especially true in the case where an ultrasonic motor is used as a drive source for vibration alarms, etc., and when the battery voltage is sufficient, the motor can be driven continuously. It is.

[Brief description of the drawings]

1 is a block diagram showing a configuration of an embodiment of an ultrasonic motor drive circuit, FIG. 2 is a load characteristic diagram of a battery, FIGS. 3 and 4 are detailed circuit diagrams of FIG. 2, and FIG. -The signal waveform diagram of each part shown in FIG. DESCRIPTION OF SYMBOLS 1 ... Control circuit 2 ... Drive duty generation circuit 3 ... Battery voltage detection circuit 4 ... Driving frequency generation circuit 5 ... AND gate circuit 6 ... Phase shift circuit 7 ... Drivers 11, 12 ... T · FF 13, 14, 25, 26, 35, 43, 44 DFF 21 24-bit counter 23 Hexadecimal presettable 22, 24 RS latch 28, 34, 45, 46 Inverters 15, 27, 29, 30, 31, 32, 33, 36, 39 Gate circuit 37, 38 Voltage divider circuit 40 Reference constant voltage 41, 42 Comparator

Claims (3)

(57) [Claims] 1. A control circuit, a battery voltage detection circuit for detecting a battery voltage using a first output signal from the control circuit, a second output signal from the control circuit, and the battery voltage detection circuit A drive duty generation circuit for intermittently outputting a drive request signal using the battery voltage information detected in the step, and a driver for generating a drive signal for intermittently driving the ultrasonic motor using the drive request signal And the battery voltage detection circuit selects a plurality of predetermined drive duties corresponding to a plurality of predetermined voltage ranges, and outputs the result to the drive duty generation circuit as a signal, whereby the ultrasonic motor An ultrasonic motor driving circuit for controlling intermittent driving. 2. A driving frequency generating circuit for generating a predetermined driving frequency signal for driving an ultrasonic motor according to an output from the control circuit, wherein the driver uses the driving request signal and the driving frequency signal. 2. The ultrasonic motor drive circuit according to claim 1, wherein the ultrasonic motor drive circuit generates a drive signal for intermittently driving the ultrasonic motor. 3. An ultrasonic motor, comprising: a phase shift circuit for adjusting a phase of the drive request signal and a phase of the drive frequency signal, wherein the driver uses an output signal of the phase shift circuit that has been shifted in phase. 2. The ultrasonic motor drive circuit according to claim 1, wherein said ultrasonic motor drive circuit is configured to generate a drive signal for intermittently driving said drive signal.